Control unit circuit for a motor vehicle, motor vehicle and operating method for the control unit circuit

1. A control unit circuit for a motor vehicle, wherein the control unit circuit comprises a control unit for providing a vehicle function and, outside a housing of the control unit, an electrical energy store for an emergency supply of the control unit, wherein the energy store is set up to supply the control unit with electrical energy if there is no supply current from an on-board electrical system of the motor vehicle, wherein, to form a circuit for the emergency supply, two electrical poles of the energy store are connected to the control unit via a cable and, in the control unit or in the energy store or on the cable, one of the two electrical poles is connected via a switching element to a ground potential of the on-board electrical system and at least one measurement circuit couples each one of the poles to the ground potential and is set up to generate a measurement signal, which is correlated with a voltage dropped between the respective pole and the ground potential, and a control circuit of the switching element is set up to keep the switching element in an electrically conductive state in normal operation of the control unit and, at least in an event that the respective measurement signal of the at least one measurement circuit indicates that the respective voltage is greater than a predetermined threshold value, to switch the switching element to an electrically non-conductive state and thus to suppress an electrical coupling, brought about by the electrical switching element, between the control unit circuit and ground potential.

2. The control unit circuit as claimed in claim 1, wherein the control circuit has a signal input for receiving a switching signal and is set up to switch the switching element to an electrically non-conductive state depending on the switching signal.

3. The control unit circuit as claimed in claim 2, wherein the control unit is set up to carry out a test routine for checking an insulation resistance of the cable and/or a load test for the energy store and, at a beginning of the test routine and/or the load test, and generate the switching signal at the signal input.

4. The control unit circuit as claimed in claim 3, wherein, during the load test, an electric current of the energy store is routed via a load resistor connected between the poles of the energy store and the switching element is kept in the electrically non-conductive state by means of the switching signal and a respective voltage of both poles of the energy store with respect to the ground potential of the cable is set to a positive value by virtue of one of the poles or a supply line of the cable being connected to a charging circuit of the control unit circuit.

5. The control unit circuit as claimed in claim 1, wherein the at least one measurement circuit comprises in each case a series circuit composed of a Zener diode and a resistance element, via which the respective pole is connected to the ground potential, wherein the threshold value is stipulated by a breakdown voltage of the Zener diode.

6. The control unit circuit as claimed in claim 5, wherein the Zener diode is arranged on a pole side and the resistance element is arranged on a ground potential side in the series circuit.

7. The control unit circuit as claimed in claim 1, wherein each measurement circuit between the respective pole and the ground potential has a resistance value of more than 1 kiloohm.

8. The control unit circuit as claimed in claim 1, wherein the switching element is an N-channel MOSFET whose source electrode is connected to the ground potential, and the control circuit provides a connection of a gate electrode of the N-channel MOSFET to a positive voltage of the control unit and/or of the energy store via a pull-up resistor and the respective measurement circuit is connected to a control input of a respective switching transistor, which connects the gate electrode to the ground potential.

9. The control unit circuit as claimed in claim 8, wherein at least one further switching transistor connects the gate electrode to the ground potential.

10. The control unit circuit as claimed in claim 1, wherein a measurement circuit is provided for each of the two poles.

11. The control unit circuit as claimed in claim 10, wherein the measurement circuits provide different resistance values between the respective pole and the ground potential.

12. The control unit circuit as claimed in claim 1, wherein the cable comprises supply lines, which each connect one of the poles to the control unit, and through the cable for one or both of the poles a respective measurement line is additionally provided for connecting the pole to the control unit while bypassing the supply lines and the control unit is set up to detect a voltage of the pole and/or a thermistor on the energy store via the at least one measurement line.

13. The control unit circuit as claimed in claim 1, wherein the control unit provides an e-call emergency call function as the vehicle function.

14. A motor vehicle comprising a control unit circuit as claimed in claim 1.

15. A method for operating a control unit circuit, which provides a control unit for providing a vehicle function and, outside a housing of the control unit, an electrical energy store for an emergency supply of the control unit, wherein the energy store supplies the control unit with electrical energy if there is no supply current from an on-board electrical system of a motor vehicle, wherein two electrical poles of the energy store are connected to the control unit via a cable and one of the two electrical poles is connected via a switching element to a ground potential of the on-board electrical system and at least one measurement circuit couples each one of the poles to the ground potential and generates a measurement signal, which is correlated with a voltage dropped between the respective pole and the ground potential, and a control circuit of the switching element keeps the switching element in an electrically conductive state in normal operation of the control unit and, at least in an event that the respective measurement signal of the at least one measurement circuit indicates that the respective voltage is greater than a predetermined threshold value, switches the switching element to an electrically non-conductive state and thus interrupts an electrical coupling to the ground potential.